NL8303029A - DEVICE FOR READING A DISC-SHAPED OPTICAL RECORD CARRIER. - Google Patents

Description

t ψ> Λ PEN 10.762 1 N.V. Philips' Incandescent light factories in Eindhoven.

Device for reading a disc-shaped optical record carrier.

The invention relates to an apparatus for reading out a disc-shaped record carrier on which video information is recorded in substantially parallel tracks according to an optically detectable structure, which apparatus is provided with an optical reading unit with a reading detector for detecting the data after cooperation with the record carrier contained in a read beam beam and a deflection element co-operating with the read beam beam for varying the radial scanning position on the record carrier, which deflection element depends on.

10 of a control signal relative to a center position is movable in two opposite directions, the device further comprising a driving device for moving the optical reading unit in a radial direction and a servo control loop for controlling the radial scanning position on the record carrier, into which servo control loop is incorporated the deflection element and a measuring detector for measuring the radial deviation of the scanning position from the desired track and deriving therefrom the control signal for the deflection element, the servo control loop comprising switching means for inactive making this servo control loop during controlled periods of time and driving means for causing the deflecting element to move at least in the middle position during these periods of time.

Such a device is known from United States patent specification 4,330,880. With the aid of the device shown in this patent specification 25 the possibility is created to quickly search for a desired program part on the record carrier, with at least a reasonable preservation of the image reproduction during this search operation.

In addition to the visual search for a desired program section, it is also possible with such record carriers to automatically search for a desired program section. The video images recorded on such a record carrier are often provided with an individual image nurmer, which is inserted as a digital signal in the raster retrace period of the video signal. This means that the a 3 n ”" 9 0 4 * PHN 10.762 2 possibility exists by entering an automatic picture visit by entering a picture number, whereby by comparing the currently read picture number and the desired picture number a control signal for the drive device. can be obtained from the optical read-out unit and this read-out unit can be moved very quickly to the desired radial position, whereby the desired video image can be read out.In this search operation, whereby very fast movements of the optical read-out element are possible, the retention of image display is no longer important, but it is important that during the search operation information is available about the position of the scanning spot on the record carrier.

The object of the invention is to indicate a device of the above-mentioned type in which this information about the position of the scanning spot remains reliably available during this automatic search operation.

It is also an object of the invention to provide a device which fulfills the above-mentioned object and also enables a search operation in a very simple manner while retaining the image display.

To this end, the invention is characterized in that the device 20 is provided with a control circuit with an input coupled to the read-out detector and an output coupled to the switching means, which control circuit is arranged for detecting read field pulses or a time-correlated synchronization signal of the video signal and supplying a periodic control signal to the switching means for making the servo control loop alternately active and inactive, the phase of this periodic control signal having a predetermined relationship to a frame pulse initiating this control signal.

The measure according to the invention first of all creates the possibility of continuing to read image numbers reliably during an automatic search operation.

To this end, the device according to the invention can be characterized in that the control device is arranged to operate the servo control loop at a time which is delayed with respect to this grid pulse with a duration that is at least slightly less than one frame period, each time after detection of a raster pulse.

By this measure it is achieved that after a detection of a raster pulse before the appearance of the next raster pulse, the 3303029 * * EHN 10.762 3 servo loop is closed again and therefore the information track is followed. This means that this frame pulse and the address signal recorded in the associated frame flyback period are read with great certainty. By initiating the control circuit, this read-out raster pulse again ensures that the servo control loop is closed again before the subsequent raster pulse occurs, and the associated address signal is read out, and so on.

This means that during such a search action the address signals are periodically read out with great certainty, that it is at all times known on which track the scanning spot is currently located, which is of great importance for controlling the drive device of the optical reading element.

The invention is characterized in that the control circuit is arranged to make the servo control loop active over a period of time, which cravings a number of frame periods and to disable this servo control loop in a subsequent period of which the time period is at least approximately corresponds to a raster flyback period of the video signal.

Since in a visual search operation the radial speed at which the optical reader is moved is considerably smaller than in an automatic search operation, the periods during which the servo control loop is closed can be considerably longer.

Since, according to the invention, it is ensured that the periods during which this servo control loop is inactive at least partly coincide with a raster retrace period of the video signal, the disturbance of the picture display occurring during these periods is achieved for at least a large part outside the displayed picture. and are therefore hardly disturbing.

The invention will be further elucidated with reference to the drawing, in which figure 1 shows an embodiment of the device according to the invention, figure 2 shows an embodiment of the control circuit used therein and figure 3 shows the signals occurring therein.

The device according to figure 1 shows a disc-shaped record carrier 1, which is connected by means of a central opening j 'J ·; * ·, * ’· λ Ό Λ V-" V "-J ij & 0 * PHN 10.762 4

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projecting shaft 2 is driven in rotating sense V. It is assumed that this record carrier 1 has information tracks on the top surface, which top surface is designed as a reflection surface, and that the record carrier material itself is transparent, so that this record carrier 5 can be read out by means of an optical read-out unit located below the record carrier.

This optical read-out unit is housed in a housing 3 and is the first to contain a radiation source 4, which generates a read-out beam A. This read-out beam A is guided via a semipermeable mirror 5, a deflection element 6 designed as a mirror and a lens system 7 to the record carrier 1 and focused through this lens system 7 to a scanning spot S. The beam of radiation reflected by the record carrier is then again guided via the lens system 7, the mirror 6 and the semipermeable mirror 5 to a detection system 8. This detection system 8 is only schematically shown and contains a read-out detector 9 for detecting the video information present in the beam of rays, which video information becomes available for further processing on a signal terminal 10.

Furthermore, this detection system 8 comprises a measuring detector 11 for measuring the deviation of the radial scanning position of the scanning spot S from the desired track. The error signal supplied by this measuring detector 11 is fed via a servo amplifier 12 and the normal switch 13 in the marked position to a driving device 14, which driving device 14 determines the angular tooth 25 of the mirror 6. This drive device 14 can for instance be formed by a galvanometer drive, in which a number of wire windings are arranged on the mirror which are situated in a magnetic field and wherein the angle of the mirror is varied against a resilience by supplying a current to these wire windings. can be honored. In this way a closed servo control loop is obtained via the beam beam A, the measuring detector 11, servo amplifier 12, drive device 14 and mirror 6, which ensures that the scanning spot S always coincides with the information track.

The housing 3 containing the optical read-out unit can be moved in radial direction by means of a worm-rack combination 15, which is driven by a motor 16. This motor 16 receives a control signal which, for example via a low-pass filter 17, controls the control signal. the driving device 14 is derived.

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As a result, during the normal scanning of the record carrier 1, an automatic adjustment is made via the radial position of the reading unit, depending on the average deflection of the mirror 6.

The device described so far is entirely similar to the device as described in U.S. Pat. No. 3,854,015 (EHN 6225). This patent also discloses some possibilities for obtaining a suitable control signal in the servo control loop with the aid of the measuring detector 11 as alternative embodiments for the drive device 14. Since the manner in which this control signal is obtained for the present invention does not Moreover, the essential importance is known from the literature. ”A multitude of solutions for this are known, will not be discussed in more detail here.

In order to have the possibility to quickly search for a desired program part, a switch 18 has been provided between the filter 17 and the motor 16, which normally takes the position drawn.

When a desired program section is quickly searched for, this switch 18 is converted using an operating unit 19, so that the motor 16 then no longer receives a control signal from the filter 17.

On the other hand, via the operating unit 19 and the switch 18, such a control signal is supplied to this motor 16 that the read-out unit is moved quickly in the desired direction.

According to the invention, the device further comprises a control circuit 20, which operates the switch 13. When this switch 13 is in the drawn position, the servo control loop consisting of the measuring detector 11, servo amplifier 12 and deflection element consisting of the mirror 6 with drive device 14 is closed, which means that the scanning spot S remains centered on the information track.

30 Has a search operation been started via the operating unit 19, i.e.

if, as a result of the switch 18 being turned off, the optical reading unit 3 is moved rapidly in the radial direction, the servo control loop will attempt, by a steadily increasing deflection of the mirror, the radial displacement of the scanning spot caused by the displacement of the reading unit 3 5 nullify.

Since the control range of this mirror 6 is, of course, limited, this is only possible to a limited extent and a moment soon occurs when the radial follower control is no longer effective, and the scanning spot

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The measure according to the invention aims to establish in a controlled manner the periods during which this servo-control loop is active or ineffective. This will be explained with reference to figure 2, in which an embodiment of the control circuit 20 is shown and figure 3 in which the signals occurring in the various look-up modes are shown within this control circuit.

The operation of the control circuit 20 will first be explained by means of a fast look-up action, i.e. a look-up action 10 in which it is not important that image reproduction is preserved, but it is important that the address signals present in the video signal are reliably read out. In the case of disc-shaped record carriers in which this type of fast, possibly automatic look-up action is desired, generally one video image per track is recorded exactly, ie two video frames. The single video image characterizing address signals are recorded at least once per video image, in a frame flyback period, e.g., the frame flyback period prior to the first frame of each video image. Of course, any frame flyback period may also contain an address signal. With these record carriers, which of course are rotated at a constant speed during reading, the time distance between successive grating pulses is known, also when the scanning spot is moved rapidly over the tracks during a search operation in radial direction. For the European television standard, this time distance is 20 msec, which will be used for the explanation of the invention below.

The embodiment shown in Figure 2 of the control circuit 20 used in the device according to the invention comprises an input terminal 20a, which is connected to the readout detector 9 (see Figure 1). The control circuit 20 further includes a detector 31 for detecting frame pulses in the read video signal. The frame pulses detected by the detector 21 are applied to a monostable flip-flop 32 which has a relaxation time slightly shorter than a frame period, e.g. 16 msec. This flip-flop 32 is preferably not retriggerable, i.e. cannot be retriggered during the relaxation time 35, e.g. due to a jamming pulse.

The non-inverting output Q of this flip-flop 32 is connected to a sub-stage 33 connected to two outputs 33a, respectively. 33b provides two signals, the repetition frequency of which is a factor of 2 and 2, respectively. 2 is less than λ "Λ 3 η o 8 O v w '-J = - ** EHN 10.762 7

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repetition rate of the raster pulse sequence. A switch 34 is connected to two of its input terminals, namely 34b, respectively. 34c connected to these outputs 3 3d resp. 33b of this partial stage 33, while a third input terminal 34a is connected to the inverting output Q of the flip-flop δ 32. The master contact of this switch 34 is connected to the input of a monostable flip-flop 35, which has a relaxation time of approximately 6 msec possession. The non-inverting output Q and the inverting output Q are resp. connected to two input terminals 36a resp. 36b of a switch 36, the master contact of which is connected to the output terminal 20c of the control circuit 20, which output terminal is coupled to the switch 13 for interrupting the servo control loop (see Figure 1). Both switches 34 and 36 are operated by a circuit 37, which has a control input 20b connected to the operating unit 19 (see figure 1). Furthermore, this circuit 37 supplies a control signal to the flip-flop 35, which ensures that this flip-flop 35 is only active during one of the modes described below.

During a fast search operation without retaining image display, switches 34 and 36 are placed in the marked position by circuit 37. The signal forms occurring during this fast look-up within the control 20 circuit are shown in Figure 3a.

If it is assumed that the fast look-up action is started just after the time to, the flip-flop 32 will already be triggered by the raster pulse ro detected at the time to.

The inverting output Q of this flip-flop has therefore become "0" at time t0 and becomes "1" again at time t1 after the relaxation time of + 16 msec. This rising edge at the time t1 triggers the flip-flop 35, whereby the inverting output Q of this flip-flop from the time t1 becomes 110 "for a period of about 6 msec until the time tg. This output signal from the flip-flop 35 is converted via the output terminal 20c is applied to the switch 13 (FIG. 1) whereby the servo control loop is closed during the time period t1-t3 and during these periods the scan spot follows the information track.

The relaxation time of the flip-flop 32 is chosen such that the time t1 falls before the time t2 at which the appearance of the next frame pulse r2 may be expected, which is after all 20 msec after the appearance of the frame pulse ro. Some space is built in to ensure that at time t1 the servo control loop corrects the scanning spot correctly positioned on the information track. 7 'Ö

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ENN 10.762 8, which of course takes some time after the servo control loop has closed at time t1. The relaxation time of the flip-flop 35 is selected such that the servo control loop remains closed until after the time when the address signal associated with the frame pulse r1 associated with the frame pulse r1 can be expected.

Since the servo control loop is closed during the time period t1-t3 and therefore the scanning spot remains centered on the information track, it is ensured that the frame pulse r1 and the associated address signal are correctly read. The read-out address signal 10 gives an indication of the radial distance traveled in the time period t0-t1. By supplying this address signal to the operating unit 19 (figure 1), the progress of the search action can hereby be controlled. This address signal can of course also be displayed.

At time t3, the servo control loop becomes inactive again.

Starting from a deflection element in the form of a mirror, which is rotatable from a central position against a resilience, this deflection element will from that moment return to its central position.

The raster pulse r1 read at time t2 again initiates flip-flop 32, which in turn results in the servo control loop being closed again at a time 20 t4 prior to the time at which the next raster pulse may be expected.

The aforementioned 6 msec relaxation time of the flip-flop 35 has, of course, been determined from the time during which the deflection element has the ability to keep the scanning spot centered on the information track at the selected radial speed of the optical reader. The determining factor for this is, on the one hand, the maximum possible deflection of this deflection element, on the other hand, the magnitude of the radial velocity of the optical reading unit.

If the greatest possible speed of the reading unit, the maximum deflection of the deflecting element and this relaxation time are correctly selected, the system will continue to operate correctly even at smaller radial speeds of the reading unit.

Figure 3b shows the signal shapes that occur when the device according to the invention is switched to the search mode while retaining image display. In this look-up action, the optical read unit is moved at a considerably lower radial speed than in the fast look-up action, as described with reference to Figure 3a. This means that the time periods during which the: o 1 2 9 - PHN 10.762 9 servo control loop can be closed is considerably longer, allowing image display.

In the control circuit according to Figure 2, this look-up mode is switched on because the operating unit 19 (Figure 1) places the switch 34 in the position 34b via the circuit 5 37 and the switch 36 in the position 36a.

Returning to Figure 3b, it can be seen that a first frame pulse ro detected just before the lookup is turned on triggers flip-flop 32. The output Q of this flip-flop is connected to the sub-stage 33, which is driven by the negative going edges of its input signal. In this search mode 2, this partial stage 33 has a dividend of 2, so that at its output 33a a signal appears as shown in figure 3b, the walk signal has a period corresponding to four frame periods. This signal is applied to the flip-flop 35, which is triggered by positive edges of that signal and the output of which is available on the non-inverting output 35 Q on the output terminal 20c for driving the switch 13 in the radial servo control loop. . First of all, this output signal 35Q causes the servo control loop to be inactive for relatively short periods, for the first time during the period t1-t3, which period again has a duration equal to the relaxation time of the flip-flop 35. The subsequent duration t3-t4, during which the servo control loop is closed, ie operating, it is almost 4 frame periods, during which period the video signal is read out and therefore undisturbed image reproduction is possible. Since the period of time during which the servo control loop is inactive in time practically coincides, a raster flyback period has just been reached that the image display disturbance occurring during this period is hardly visible, ie at most only produces some disturbance in the bottom and top picture lines of a displayed picture. video image.

Finally, figure 2 shows the possibility of a third scanning mode, the so-called pause mode. The optical reader is stopped during this pause mode. The servo control loop is always made alternately active and inactive by means of the control circuit 20 35. Due to the fact that the readout unit is stationary, it is possible to select the period of time during which the servo control loop operates considerably longer than in the look-up actions described above.

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This is achieved by placing the switch 34 in the position 34c, whereby the output 33b of the sub-stage 33 is coupled to the flip-flop 35. The sub-stage 33 supplies to this output 33b a signal that g has a division ratio of 2 with respect to its input signal.

5 E.e.a. results in the servo control loop alternately becoming inoperative for a duration of 6 msec and operating for a duration approximately corresponding to 256 frame periods. In this pause mode, therefore, the same scene of 256 video frames can be repeatedly displayed. The image display can also be suppressed during this pause mode. After all, the main function of this pause mode is to keep the scanning spot positioned on the same part of the record carrier.

Of course, a number of refinements are still possible with regard to the system described above. For example, in the illustrated embodiment, in the image search search, the time period during which the servo control loop is interrupted is 6 msec, which is due to the fact that the control circuit required for this is derived with as few additions as possible. control circuit of the fast search. If it is desirable for certain applications to be able to select a different time period for the servo control loop to be inoperative, this is of course possible by adding an additional monostable flip-flop.

When the servo control loop is switched on again after an inactive period, it is of course important that the scanning spot is centered again on the information track as quickly and as reliably as possible. Possibilities for this have been indicated in the aforementioned U.S. Patent No. 4,330,880, especially. figure 5.

For the circuit to be used for this purpose, reference is therefore made to this US patent, which is hereby deemed to be included in this application.

Embodiments of the deflection element to be used in the device of the invention are found in U.S. Patent Re 29,963, which is also contemplated in the present application.

The manner in which the address signals are recorded on the record carrier during the frame flyback periods of the video signal is of minor importance to the present invention. For illustrative purposes, reference is made only to commercially available "C3" 5 5 2 2 PHN 10.762 11 disc-shaped video plates of the "Laservision" type.

In the described embodiment of the device according to the invention, it is assumed that raster pulses are detected in the control circuit. It is of course also possible to detect another synchronization signal present in the video signal instead of these 5 pulse pulses. For example, one can detect the line pulses. By means of a counter can be used to derive pulses from this that are one grid period apart. By synchronizing this counter once with a frame pulse, a pulse series can thus be obtained which substantially coincides with the frame pulse series.

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Claims (4)

1. Device for reading out a disc-shaped record carrier on which video information is recorded in substantially parallel tracks, according to an optically detectable structure, which device is provided with an optical reading unit with a reading detector for detecting the data after cooperation with the record carrier, information contained in a read beam beam and a deflection element co-operating with the read beam beam for varying the radial scanning position on the record carrier, which deflection element is movable in two opposite directions relative to a center position 10 the device further comprising a driving device for radially displacing the optical reading unit and a servo control loop for controlling the radial scanning position on the record carrier, in which servo control loop is included the deflection element and a measuring detector for hey measuring the radial deviation of the scanning position from the desired track and deriving therefrom the control signal for the deflection element, the servo control loop comprising switching means for inactivating this servo control loop during controlled periods of time and driving means for during this time. causing the deflection element to move at least in the direction of the central position, characterized in that the device is provided with a control circuit with an input coupled to the read-out detector and an output coupled to the switching means, which control circuit is arranged for detecting read frame pulses 25 or a time-correlated synchronization signal of the video signal and supplying a periodic control signal to the switching means for making the servo control loop alternately active and inactive, the phase of this periodic control signal having a predetermined relationship to a this control signal initiating frame pulse. 2. Device as claimed in claim 1, characterized in that the control device is arranged to make the servo control loop active at a time which is delayed with respect to this raster pulse with a duration which is at least slightly less than one raster period, each time after detection of a raster pulse. 3. Device as claimed in claim 2, characterized in that the control device is arranged for operating the servo control loop in each case over a period of time which is at least greater than the period of time 8303029 -EHN 10.762 13 comprising the start of the raster pulse and the end of the address signal recorded in the frame retrace period of the video signal. Device according to claim 1 with the. characterized in that the control circuit is arranged to operate the servo control loop 5 over a time period comprising a number of frame periods and disable this servo control loop in a subsequent period whose time period corresponds at least approximately to a frame flyback period of the video signal. 10 15 20 25 30 35 ”Q